CN117444750A - Clamping and polishing device for pump body machining - Google Patents

Abstract

The invention relates to the technical field of polishing equipment, and particularly discloses a clamping polishing device for pump body processing, wherein an impeller seat is provided with an impeller groove for placing an impeller, a telescopic device is arranged in a chassis, the output end of the telescopic device is provided with a clamping piece, the clamping piece can be clamped on the impeller, a guide rail is connected with the output end of the telescopic device and is provided with a T-shaped chute, a support piece is provided with a support shaft, the support shaft is provided with an annular flange, the annular flange is matched in the T-shaped chute, a limiting plate is coaxially arranged on the outer peripheral side of the support shaft through a through hole, the limiting plate is slidably arranged on the guide rail, and the support piece is connected with the limiting plate through an elastic piece; two polishing rollers are rotatably arranged on the support piece, and a polishing gap is formed between the two polishing rollers; the guide rail is provided with a rack, and the gear mechanism is connected with the rack and the grinding roller. According to the clamping polishing device for pump body processing, the supporting shaft and the coil springs improve the adaptability of the polishing roller to impellers of different types or different models.

Description

Clamping and polishing device for pump body machining

Technical Field

The invention relates to the technical field of polishing equipment, in particular to a clamping polishing device for pump body machining.

Background

When the impeller of the centrifugal pump is processed, residues such as burrs and the like are generated on the blades, and the residues are polished to ensure the performance of the centrifugal pump. Traditional mode of polishing is manual to hand polisher or angle grinder and polishes the blade, and the efficiency of polishing is lower, and is consuming time and power. In the related art, some devices have improved this, and a matched grinder is provided for the shape and thickness of the blade, and the blade is automatically ground by using the grinder. However, in practice, the grinding tool is only suitable for impellers of the same type, and among impellers of different types, the grinding tool cannot be used in a cross-type mode due to different radians and thicknesses of the blades, so that the adaptability of the grinding tool to impellers of different types or different types is weak.

Accordingly, there is a need in the art for a clamping and polishing device for pump body machining that addresses the above-described problems.

Disclosure of Invention

The invention provides a clamping and polishing device for pump body machining, and aims to solve the problem that in the related art, the adaptability of grinding tools to impellers of different types or different models is weak.

The clamping and polishing device for pump body machining comprises a machine case, an impeller seat and a polishing assembly, wherein the impeller seat is arranged in the machine case and is provided with an impeller groove, the impeller groove is used for placing an impeller, a telescopic device positioned above the impeller seat is arranged in the machine case, the output end of the telescopic device is provided with a clamping piece, and the clamping piece can be clamped on the upper end face of the impeller; the polishing assembly comprises a guide rail, a support piece, a limiting plate and a gear mechanism, wherein the guide rail is connected with the output end of the telescopic device and is provided with a T-shaped chute extending along the radial direction of the impeller, the support piece is provided with a vertical support shaft, the top end of the support shaft is provided with an annular flange, the annular flange is matched in the T-shaped chute, and the annular flange can slide along the length direction of the T-shaped chute and can rotate around the axis of the support shaft; the limiting plate is provided with a through hole and is coaxially arranged on the outer peripheral side of the supporting shaft through the through hole, the limiting plate is slidably arranged on the guide rail along the length direction of the T-shaped chute, and the supporting piece is connected with the limiting plate through an elastic piece; two vertical polishing rollers are rotatably arranged on the support piece, and a polishing gap for the blades of the impeller to pass through is formed between the two polishing rollers; the guide rail is provided with a rack extending along the length direction of the T-shaped chute, and the gear mechanism is arranged on the support shaft and is connected with the rack and the polishing roller, so that when the support shaft slides, the rack triggers the polishing roller to rotate through the gear mechanism.

Preferably, the gear mechanism comprises a shaft sleeve, a second gear and a third gear, wherein the shaft sleeve is positioned between the supporting shaft and the limiting plate and is rotationally sleeved on the supporting shaft, and the top end of the shaft sleeve is provided with a first gear meshed with the rack; the support piece comprises a support shell, the bottom end of the shaft sleeve stretches into the support shell, and the second gear is sleeved at the bottom end of the shaft sleeve; the polishing roller is coaxially provided with gear shafts extending into the supporting shell, the number of the third gears is equal to that of the gear shafts in a one-to-one correspondence manner, and the third gears are sleeved on the corresponding gear shafts and meshed with the second gears.

Preferably, the elastic piece comprises a coil spring sleeved on the outer peripheral side of the shaft sleeve, the supporting shell is provided with a ring sleeve sleeved on the outer peripheral side of the coil spring, the upper end of the ring sleeve is rotationally connected with the limiting plate, the outer peripheral wall of the ring sleeve is elastically and slidably connected with a pin shaft, the limiting plate is provided with an extending part, the pin shaft is positioned between the extending part and the supporting shell, the top end of the pin shaft is hemispherical and elastically props against the extending part, and when the blade is reversed and approaches the polishing roller, the blade drives the polishing roller and the supporting shell to rotate around the axis of the supporting shaft, and the pin shaft is separated from the extending part; when the blade rotates forward and enters the polishing gap, the blade carries the polishing roller and the supporting shell to rotate reversely, and the pin shaft is pressed into the inner side of the extension part through the hemispherical top end of the pin shaft.

Preferably, a placing cavity is arranged in the impeller seat and is positioned below the impeller groove, a motor is arranged in the placing cavity, and an output shaft of the motor is coaxially connected with the impeller.

Preferably, a pressure sensor is arranged on the guide rail, a controller is arranged in the case, the pressure sensor is connected with the motor through the controller, when the grinding roller is out of contact with the blade in the reverse rotation state, the pin shaft is in contact with the pressure sensor, and the pressure sensor changes the steering direction of the motor according to pressure change.

Preferably, the clamping piece comprises a clamping ring plate, the clamping ring plate is clamped at a hub of the impeller, a position sensor is arranged at one end, close to the telescopic device, of the guide rail, the position sensor is connected with the motor through the controller, when the blade is polished from outside to inside, the polishing roller drives the support shaft to slide along the length direction of the T-shaped chute, and when the support shaft reaches a preset position of the position sensor, the position sensor changes the steering direction of the motor through the controller.

Preferably, the guide rail is detachably connected with the output end of the telescopic device, the number of the blades is even, and the polishing assemblies are two and symmetrical relative to the axis of the impeller.

Preferably, a collection assembly is arranged in the case, the collection assembly comprises a dirt collection box and an exhaust pipe, and the dirt collection box is positioned below the impeller seat and is arranged on the case; the first end of the exhaust tube faces to the impeller on the impeller seat, the exhaust fan is mounted on the outer side wall of the dirt collecting box, and the second end of the exhaust tube is communicated with the exhaust fan.

Preferably, the first end of the exhaust pipe is in a horn shape facing the impeller.

Preferably, the number of the exhaust fans is two and the exhaust fans are symmetrical about the axis of the impeller on the impeller seat, the number of the exhaust fans is equal to the number of the exhaust fans which are in one-to-one correspondence, and the exhaust fans are communicated with the corresponding exhaust fans.

By adopting the technical scheme, the invention has the beneficial effects that:

the support piece enables the grinding roller to have larger flexibility in grinding through the arrangement of the support shaft, so that the reverse rotation blades can be avoided, and the forward rotation blades can be conveniently inserted. Meanwhile, when blades with different radians are polished, the polishing roller can flexibly adapt to the blades with various radians in a revolution mode. When blades with different thicknesses are inserted into the polishing gap, the two polishing rollers can be tightly attached to the front surface and the back surface of the blade under the action of the elastic piece, so that the blade is tightly contacted with the blade, polishing is facilitated, and therefore, the design mode promotes the adaptability of the polishing rollers to impellers of different types or different models.

Drawings

Fig. 1 is a schematic perspective view of a clamping and polishing device for pump body processing according to the present invention.

Fig. 2 is a perspective cross-sectional view of the clamping and polishing device for pump body processing according to the present invention.

Fig. 3 is a schematic view of the structure of the telescopic device to the impeller seat portion of the present invention.

Fig. 4 is a perspective cross-sectional view of the rail-to-rack portion of the present invention.

Fig. 5 is a schematic partial structural view of a sanding assembly of the present invention.

Fig. 6 is a schematic view of yet another partial construction of a sanding assembly of the present invention.

Fig. 7 is a partial structural schematic view of the guide rail of the present invention.

Fig. 8 is a schematic view of a partial structure of the grinding roller of the present invention avoiding a reversed blade.

Fig. 9 is a partial schematic view of the blade of the present invention as it enters the sanding gap.

Fig. 10 is a perspective view of the limiting plate of the present invention.

Fig. 11 is a schematic cross-sectional view of the baffle-to-impeller portion of the present invention.

Reference numerals:

1. a chassis; 11. a work table; 12. an opening/closing door; 13. a telescoping device; 14. clamping the annular plate; 15. a walking wheel; 2. an impeller seat; 21. a cross plate; 3. a polishing assembly; 31. a guide rail; 311. t-shaped sliding grooves; 312. a rack; 313. a position sensor; 32. a limiting plate; 321. an extension; 33. a gear mechanism; 331. a shaft sleeve; 332. a second gear; 333. a third gear; 334. a first gear; 34. a support case; 341. a ring sleeve; 3411. a pressure sensor; 342. a pin shaft; 35. a support shaft; 351. an annular flange; 36. a coil spring; 37. a grinding roller; 4. an impeller; 41. a blade; 5. a motor; 6. a dirt collection box; 7. an exhaust tube; 8. and (5) an exhaust fan.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

The clamping and polishing device for pump body machining according to the present invention is described below with reference to fig. 1 to 11.

Embodiment 1 as shown in fig. 1 to 6, the clamping and polishing device for pump body processing of the present invention comprises a housing 1, an impeller seat 2 and a polishing assembly 3. The walking wheels 15 are arranged at four corners of the bottom of the chassis 1 and are convenient to travel, each corner is further connected with a vertical threaded rod in a threaded manner, a supporting plate is arranged at the bottom end of each threaded rod, after the chassis 1 moves to a designated position, the threaded rods rotate downwards, the supporting plates are gradually grounded and slowly lift the chassis 1, so that the walking wheels 15 are separated from the ground, and temporary fixation of the chassis 1 is realized. The case 1 is provided with a picking and placing opening communicated with the internal space and the outside, the picking and placing opening is hinged with an opening and closing door 12, when the opening and closing door 12 is closed, the picking and placing opening can be closed, and at the moment, the opening and closing door 12 can be locked, so that the outside impurities are prevented from entering the case 1. The locking and unlocking techniques of the door 12 are conventional in the art, and will not be described in detail herein.

The machine case 1 is internally provided with a workbench 11, the impeller seat 2 is arranged on the workbench 11, the top end surface of the impeller seat 2 is provided with an impeller groove which is concave downwards, the impeller groove is round and is vertically arranged on the axis, and the impeller groove is used for coaxially placing the impeller 4. The machine case 1 is internally provided with a telescopic device 13 positioned above the impeller seat 2, the telescopic device 13 can be an electric telescopic rod, a hydraulic cylinder or an air cylinder, and the like, the output end of the telescopic device 13 is provided with a push column, the bottom end of the push column is fixed with a clamping piece, and the clamping piece can be clamped on the upper end face of the impeller 4. In particular, as shown in connection with fig. 2 and 10, the clamping member comprises a clamping ring plate 14 coaxial with the impeller 4, the clamping ring plate 14 being clamped at the hub of the impeller 4, the co-action of the clamping ring plate 14 and the impeller groove limiting the axial and radial position of the impeller 4 such that the impeller 4 can only rotate.

The polishing assembly 3 includes a guide rail 31, a support member, a limiting plate 32 and a gear mechanism 33, wherein one end of the guide rail 31 is detachably connected with the output end of the telescopic device 13, and the detachable connection can be in a concrete form of a bolt connection or a screw connection, which is not described in detail herein. The guide rail 31 has a T-shaped chute 311 extending in the radial direction of the impeller 4, and both ends of the T-shaped chute 311 are closed. The support includes a support case 34, and the support case 34 has a vertical support shaft 35, specifically, a bottom end of the support shaft 35 is connected to a bottom wall of the support case 34, and a top end of the support shaft 35 passes through a top wall of the support case 34 and extends above the support case 34. The top end of the supporting shaft 35 is provided with a coaxial annular flange 351, the T-shaped chute 311 comprises a vertical groove in the middle and two side grooves on two sides, the top end of the supporting shaft 35 is arranged in the vertical groove in a penetrating mode, and the outer edges of the annular flange 351 are respectively matched with the two side grooves. Thus, the side slots limit only the up and down movement of the annular flange 351 and do not limit the rotation of the annular flange 351 and the sliding of the annular flange 351 within the T-shaped chute 311. The design is such that the annular flange 351 can slide along the length of the T-shaped chute 311 and also can rotate about the axis of the support shaft 35. The guide rail 31 can bear the weight of the support shaft 35 and the support shell 34 via the annular flange 351.

The limiting plate 32 is provided with a through hole, the limiting plate 32 is coaxially arranged on the outer peripheral side of the supporting shaft 35 through the through hole, the side walls of the two sides of the T-shaped sliding groove 311 are respectively provided with a sliding groove extending along the length direction of the sliding groove, the limiting plate 32 is positioned on the inner side of the T-shaped sliding groove 311, and the limiting plate 32 is provided with two sliding strips respectively in sliding fit with the two sliding grooves. The support case 34 is located under the stopper plate 32, and the support case 34 and the stopper plate 32 are connected by an elastic member including a coil spring 36.

The bottom of the supporting shell 34 is rotatably provided with two vertical polishing rollers 37, when the clamping ring plate 14 is clamped on the upper end face of the impeller 4, the bottom ends of the polishing rollers 37 are flush with the root parts of the blades 41 of the impeller 4, when the torsion spring is in a natural state, the two polishing rollers 37 are distributed along the length direction of the T-shaped sliding groove 311, and a polishing gap for the blades 41 of the impeller 4 to pass through is formed between the two polishing rollers 37. The side wall of one side of the T-shaped chute 311 is provided with a containing groove, a rack 312 is arranged in the containing groove, and the rack 312 extends along the length direction of the T-shaped chute 311 and is fixedly connected with the guide rail 31. The gear mechanism 33 is provided on the support shaft 35 and connects the rack 312 and the grinding roller 37 so that the rack 312 causes the grinding roller 37 to rotate through the gear mechanism 33 when the support shaft 35 slides.

The impeller seat 2 is internally provided with a placement cavity positioned below the impeller groove, a transverse plate 21 is fixed in the placement cavity, a motor 5 positioned in the placement cavity is fixedly installed on the transverse plate 21, an output shaft of the motor 5 is coaxially connected with the impeller 4, and the impeller 4 can be disassembled from the output shaft of the motor 5 to facilitate replacement.

For ease of understanding, the rotation of the grinding roller 37 about the axis of the support shaft 35 is set to revolution, and the rotation of the grinding roller 37 about its own axis is set to autorotation.

In the initial state, the supporting shaft 35 and the annular flange 351 are both positioned at one end of the guide rail 31, which is away from the telescopic device 13, at the moment, the impeller 4 can be controlled to rotate reversely through the motor 5, the impeller 4 drives the blades 41 to rotate reversely, and when the blades 41 are pressed against the grinding roller 37, the blades 41 push the grinding roller 37 to rotate together with the supporting shell 34, so that avoidance of the blades 41 is realized. After the blades 41 pass over the grinding roller 37, the motor 5 can control the impeller 4 to rotate positively, and the impeller 4 drives the blades 41 to rotate positively. At this time, the grinding roller 37 and the supporting case 34 have been restored to the original positions by the coil spring 36, and as shown in fig. 9, the blades 41, which are rotated in the normal direction, can be inserted into the grinding gap and drive one of the grinding rollers 37 to revolve by a certain angle, and the other grinding roller 37 is also affected by this to revolve by a corresponding angle. So far, one polishing roller 37 is positioned at the front side of the blade 41, the other polishing roller 37 is positioned at the rear side of the blade 41, then the blade 41 continues to rotate, the polishing roller 37 positioned at the front side slides along the length direction of the T-shaped sliding groove 311 under the driving of the blade 41, and then the polishing roller 37 with the rear side slides together through the supporting shell 34, at the moment, the coil spring 36 is deformed under the influence of the revolution of the previous polishing roller 37, and the elastic force generated by the coil spring 36 can bring the two polishing rollers 37 to tightly press the front surface and the back surface of the blade 41. Meanwhile, the polishing roller 37 slides synchronously through the supporting shell 34 and the supporting shaft 35, and the rack 312 triggers the polishing roller 37 to rotate through the gear mechanism 33, so that the front side polishing roller 37 can polish the front surface of the blade 41 when rotating, and the rear side polishing roller 37 can polish the rear surface of the blade 41 when rotating.

When the two polishing rollers 37 polish the blades 41 from outside to inside, the motor 5 can drive the blades 41 to rotate reversely, the blades 41 gradually withdraw from the polishing gap, the blades 41 push the two polishing rollers 37 back, and when the blades 41 are completely separated from the polishing gap, the two polishing rollers 37 are just reset. At this time, if the next blade 41 is to be polished, the above steps may be repeated until all the blades 41 on the impeller 4 are polished.

From the above, the supporting shell 34 is arranged by the supporting shaft 35, so that the polishing roller 37 has greater flexibility in polishing, not only can avoid the reverse rotation of the blade 41, but also is convenient for inserting the forward rotation of the blade 41, and meanwhile, when the blades 41 with different radians are polished, the polishing roller 37 can flexibly adapt to the blades 41 with various radians in a revolution manner. When the blades 41 with different thicknesses are inserted into the polishing gap, the polishing roller 37 can be tightly attached to the front or back of the blades 41 under the action of the coil springs 36, so that the close contact with the blades 41 is realized, polishing is facilitated, and therefore, the design mode promotes the adaptability of the polishing roller 37 to impellers 4 with different types or models.

The gear mechanism 33 includes a shaft sleeve 331, a second gear 332, and a third gear 333, where the shaft sleeve 331 is coaxial with the support shaft 35 and is located between the support shaft 35 and the limiting plate 32, in other words, the through hole of the limiting plate 32 is larger, there is an annular gap between the limiting plate and the support shaft 35, and the shaft sleeve 331 is disposed in the annular gap. The inner peripheral wall of the shaft sleeve 331 is rotatably sleeved on the supporting shaft 35, a first gear 334 is sleeved on the top end of the shaft sleeve 331, and the first gear 334 is meshed with the rack 312. The bottom end of the shaft sleeve 331 passes through the top wall of the supporting shell 34 and extends into the supporting shell 34, and the second gear 332 is sleeved at the bottom end of the shaft sleeve 331. The top end of the grinding roller 37 is coaxially provided with gear shafts, the gear shafts penetrate through the bottom wall of the supporting shell 34 and extend upwards into the supporting shell 34, the number of the third gears 333 is equal to and corresponds to that of the gear shafts one by one, the third gears 333 are sleeved on the corresponding gear shafts, and each third gear 333 is meshed with the second gear 332.

When the supporting shaft 35 and the polishing roller 37 slide synchronously, the shaft sleeve 331 is driven to slide, the shaft sleeve 331 drives the first gear 334 to slide along the length direction of the T-shaped sliding groove 311, under the meshing action of the first gear 334 and the rack 312, the first gear 334 drives the shaft sleeve 331 to rotate, the shaft sleeve 331 drives the second gear 332 to rotate, the second gear 332 drives the third gear 333 to rotate, and then the rotation of the polishing roller 37 is controlled, so that the effect of polishing the blade 41 is realized.

With particular reference to fig. 5 and 10, the coil spring 36 is disposed around the outer periphery of the boss 331, the bottom end of the coil spring 36 is fixedly connected to the top surface of the support case 34, and the top end of the coil spring 36 is fixedly connected to the stopper plate 32. The supporting shell 34 is fixed with a ring sleeve 341, the ring sleeve 341 is sleeved on the outer peripheral side of the coil spring 36, the upper end of the ring sleeve 341 is rotationally connected with the limiting plate 32, the outer peripheral wall of the ring sleeve 341 is elastically and slidably connected with a pin shaft 342, specifically, the outer peripheral wall of the ring sleeve 341 is fixed with a protruding block, a vertical accommodating groove is arranged in the protruding block, a pin shaft 342 is slidably matched in the accommodating groove, and the bottom end of the pin shaft 342 is connected with the protruding block through a spring. The limiting plate 32 has an extension 321, and the pin 342 is located between the extension 321 and the support shell 34, where the top end of the pin 342 is hemispherical and elastically abuts against the extension 321.

Referring to fig. 5 to 8 with emphasis, when the blade 41 is reversed and approaches the grinding roller 37, the blade 41 rotates around the axis of the support shaft 35 with the grinding roller 37 and the support case 34, the pin 342 gradually disengages from the extension 321, and after the pin 342 is completely disengaged from the extension 321, the pin 342 is sprung upward under the action of the spring. After that, the reversed blade 41 and the polishing roller 37 are gradually separated from contact, the avoidance of the blade 41 by the polishing roller 37 is finished, under the action of the coil spring 36, the polishing roller 37 and the supporting shell 34 rotate to the original position, the supporting shell 34 rotates with the pin shaft 342 through the annular sleeve 341, the ejected pin shaft 342 is stopped at the edge of the extending part 321, vibration is generated at the moment of stopping, and the vibration enables dust on the polishing roller 37 to fall down, so that the polishing roller 37 can be self-cleaned to a certain extent, and continuous use of the polishing roller 37 is ensured.

When the blade 41 rotates forward and enters the grinding gap, the blade 41 rotates in the reverse direction with the grinding roller 37 and the support case 34, and it is understood that this reverse rotation is the revolution described above, but only the rotation direction of the grinding roller 37 and the support case 34 at this time is opposite to the rotation direction when the reverse rotation blade 41 is avoided, and the pin 342 is pressed again into the inside of the extension 321 through the hemispherical tip thereof.

With particular reference to figures 2 and 3, the number of blades 41 is even, and the grinding assembly 3 has two and is symmetrical about the axis of the impeller 4. The design makes two polishing assemblies 3 polish two opposite blades 41 simultaneously, increases the number of blades 41 polished once, and improves polishing efficiency.

In order to achieve collection of dust falling from the grinding roller 37 and the blade 41, the present invention also provides example 2.

Embodiment 2 with continued reference to fig. 2 and 3 based on embodiment 1, a collection assembly is provided in the chassis 1, the collection assembly includes a dirt collection box 6 and an exhaust pipe 7, and the dirt collection box 6 is located below the impeller seat 2 and mounted on the chassis 1. The first end of exhaust column 7 is towards impeller 4 department on the impeller seat 2, and the first end of exhaust column 7 is the loudspeaker form towards impeller 4 position, and exhaust fan 8 is installed to the lateral wall of dirt collection box 6, and exhaust fan 8 and dirt collection box 6's inner space intercommunication, the second end and the air intake intercommunication of exhaust fan 8 of exhaust column 7. The outer side wall of the dirt collecting box 6 is also provided with a vent, and the vent is provided with a separation net.

When all blades 41 of the impeller 4 are polished, the exhaust fan 8 can be started, and the dust polished on the impeller 4 is pumped into the dirt collection box 6 by the exhaust fan 8 through the exhaust fan 7, so that dust collection is realized. The separation net is used for exhausting air by sucking the air in the dirt collecting box 6, blocking down the dust in the air, collecting the dust in the dirt collecting box 6, and avoiding the influence of the dust scattering in the external environment on human health. The first end of the exhaust pipe 7 is in a horn-shaped design, so that wind and dust can be conveniently guided into the exhaust pipe 7.

Wherein, exhaust fan 7 has two and about the axis symmetry of impeller 4 on the impeller seat 2, exhaust fan 8 and exhaust fan 7 quantity equals and the one-to-one, and the air intake of exhaust fan 8 communicates with corresponding exhaust fan 7.

The design has increased the effect that the bits of powder were extracted by air exhauster 8 like this, has promoted the clean effect on the bits of powder follow impeller 4 and impeller seat 2, simultaneously, has also accelerated the collection of bits of powder.

In order to promote the automation of the device, the invention also provides an embodiment 3.

In embodiment 3, with continued reference to fig. 3 to 8 based on embodiment 2, the guide rail 31 is provided with a pressure sensor 3411, the pressure sensor 3411 is located outside the ring 341, the casing 1 is provided with a controller, and the pressure sensor 3411 is connected to the motor 5 through the controller. After the pin 342 is disengaged from the extension 321 and ejected, the reversed blade 41 continues to rotate with the grinding roller 37 and the pin 342, and the pin 342 is pressed into the lower surface of the rail 31 by its hemispherical tip and approaches the pressure sensor 3411. When the grinding roller 37 is out of contact with the blade 41 in the reversed state, the pin 342 is rotated just to the pressure sensor 3411 and is in contact with the pressure sensor 3411, at which time the grinding roller 37 is out of the restriction of the blade 41 and is reset by the coil spring 36. The pressure value between the pin 342 and the pressure sensor 3411 will also be suddenly reduced, and the pressure sensor 3411 changes the steering direction of the motor 5 according to the pressure change between the pressure sensor and the pin 342, so that the reverse rotation movement of the blade 41 is adjusted to the forward movement by the motor 5, and the effect that the blade 41 automatically enters the polishing gap is achieved. As can be appreciated, the specific principle of the pressure sensor 3411 to change the direction of the motor 5 is: the pressure sensor 3411 first transmits a signal of the measured pressure change to the controller, the controller analyzes and calculates the signal, and the controller changes the steering of the motor 5 according to the analysis result.

The end of the guide rail 31 near the telescopic device 13 is provided with a position sensor 313, specifically, the position sensor 313 is arranged on the inner side of the T-shaped chute 311, the position sensor 313 is connected with the motor 5 through a controller, and the position sensor 313 can be a photoelectric sensor or an ultrasonic sensor. When the polishing roller 37 polishes the blade 41 from outside to inside, the supporting shaft 35 is driven to slide along the length direction of the T-shaped chute 311, when the supporting shaft 35 reaches the preset position of the position sensor 313, the position sensor 313 changes the steering direction of the motor 5 through the controller according to the detected signal, thereby the blade 41 is changed from positive to reverse through the motor 5, the blade 41 is further retreated from the polishing gap, and the rotation to the polishing of the next blade 41 is facilitated. The principle of the position sensor 313 changing the steering direction of the motor 5 is substantially identical to that of the pressure sensor 3411, and will not be described here again.

Referring to fig. 1 to 11, the implementation flow of the present invention is:

taking a polishing assembly 3 as an example, first, the opening and closing door 12 is opened, the impeller 4 is placed in the impeller groove, and after the impeller 4 is placed in the groove, the impeller groove is coaxial. After that, the guide rail 31 and the clamping ring plate 14 are controlled to synchronously move downwards through the telescopic device 13, and when the clamping ring plate 14 is clamped at the hub of the impeller 4, the bottom end of the grinding roller 37 just abuts against the wheel disc of the impeller 4, namely, the bottom end of the grinding roller 37 is flush with the root of the blade 41. The impeller 4 can only rotate at this time, and the movement in other directions is restricted. Next, the output shaft of the motor 5 is abutted against the impeller 4.

Then, the impeller 4 is driven to rotate reversely by the motor 5, the blade 41 pushes the grinding roller 37 to revolve and deflect to one side, the grinding roller 37 achieves avoiding of the blade 41, after the two are separated, the grinding roller 37 is reset under the action of the coil spring 36, meanwhile, the motor 5 is instructed by the pressure sensor 3411 to change steering, the motor 5 drives the impeller 4 to rotate positively, the blade 41 starts to enter a grinding gap, when the blade 41 just enters the grinding gap, the grinding roller 37 is driven to revolve a small amount, and the revolution direction is opposite to the revolution direction when the grinding roller 37 avoids the blade 41. Thereafter, one of the grinding rollers 37 is located on the front side in the rotational direction of the blade 41, the other grinding assembly 3 is located on the rear side in the rotational direction of the blade 41, and the two grinding rollers 37 are abutted against the front and rear sides of the blade 41 by the coil springs 36. When the blade 41 continues to rotate forward, the two grinding rollers 37 slide along the length direction of the T-shaped chute 311, and under the action of the gear mechanism 33 and the rack 312, the two grinding rollers 37 spin and grind the front and rear surfaces of the blade 41, respectively.

After the polishing of the blade 41 is completed, the polishing roller 37 also brings the support shaft 35 to a preset position through the support housing 34, the position sensor 313 changes the steering of the motor 5 again according to the detection signal, and the motor 5 controls the blade 41 to reverse and exit the polishing gap. When the blade 41 is completely withdrawn, the components of the sharpening assembly 3 are also reset in conjunction, and the motor 5 continues to drive the next blade 41 past the sharpening roller 37, and the next blade 41 starts the sharpening process, and so on, until all blades 41 are sharpened.

When the grinding roller 37 grinds the blades 41, the dust falling off from the grinding roller 37 and the blades 41 can fall onto the wheel disc of the impeller 4 and the impeller seat 2, and after all the blades 41 are ground, the suction fan 8 pumps the dust into the dirt collecting box 6 through the suction pipe 7, so that collection is realized.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

While embodiments of the present invention have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the invention, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the invention.

Claims (10)

1. Clamping and polishing device for pump body machining, comprising a case (1), and further comprising:

the impeller seat (2), the impeller seat (2) is arranged in the chassis (1) and is provided with an impeller groove, the impeller groove is used for placing an impeller (4), a telescopic device (13) positioned above the impeller seat (2) is arranged in the chassis (1), the output end of the telescopic device (13) is provided with a clamping piece, and the clamping piece can be clamped on the upper end face of the impeller (4);

the polishing assembly (3), the polishing assembly (3) comprises a guide rail (31), a supporting piece, a limiting plate (32) and a gear mechanism (33), the guide rail (31) is connected with the output end of the telescopic device (13) and is provided with a T-shaped sliding groove (311) extending along the radial direction of the impeller (4), the supporting piece is provided with a vertical supporting shaft (35), the top end of the supporting shaft (35) is provided with an annular flange (351), the annular flange (351) is matched in the T-shaped sliding groove (311), and the annular flange (351) can slide along the length direction of the T-shaped sliding groove (311) and can rotate around the axis of the supporting shaft (35); the limiting plate (32) is provided with a through hole and is coaxially arranged on the outer peripheral side of the supporting shaft (35) through the through hole, the limiting plate (32) is slidably arranged on the guide rail (31) along the length direction of the T-shaped sliding groove (311), and the supporting piece is connected with the limiting plate (32) through an elastic piece; two vertical polishing rollers (37) are rotatably arranged on the support piece, and a polishing gap for passing through a blade (41) of the impeller (4) is formed between the two polishing rollers (37); the guide rail (31) is provided with a rack (312) extending along the length direction of the T-shaped chute (311), and the gear mechanism (33) is arranged on the support shaft (35) and is connected with the rack (312) and the polishing roller (37), so that when the support shaft (35) slides, the rack (312) triggers the polishing roller (37) to rotate through the gear mechanism (33).

2. Clamping and polishing device for pump body machining according to claim 1, characterized in that the gear mechanism (33) comprises:

the shaft sleeve (331), the shaft sleeve (331) is located between the supporting shaft (35) and the limiting plate (32), and is rotatably sleeved on the supporting shaft (35), and a first gear (334) meshed with the rack (312) is arranged at the top end of the shaft sleeve (331);

the second gear (332), the said support piece includes supporting the shell (34), the bottom of the said axle sleeve (331) stretches into the said supporting the shell (34), the said second gear (332) is sleeved in the bottom of the said axle sleeve (331);

the third gears (333), the grinding roller (37) is coaxially provided with gear shafts extending into the supporting shell (34), the number of the third gears (333) is equal to and corresponds to that of the gear shafts one by one, and the third gears (333) are sleeved on the corresponding gear shafts and meshed with the second gears (332).

3. Clamping and polishing device for pump body processing according to claim 2, characterized in that the elastic member comprises a coil spring (36) sleeved on the outer peripheral side of the shaft sleeve (331), the supporting shell (34) is provided with a ring sleeve (341) sleeved on the outer peripheral side of the coil spring (36), the upper end of the ring sleeve (341) is rotationally connected with the limiting plate (32), the outer peripheral wall of the ring sleeve (341) is elastically and slidingly connected with a pin shaft (342), the limiting plate (32) is provided with an extending part (321), the pin shaft (342) is positioned between the extending part (321) and the supporting shell (34), the top end of the pin shaft (342) is hemispherical and elastically props against the extending part (321), and when the blade (41) is reversed and approaches to the polishing roller (37), the blade (41) rotates around the axis of the supporting shaft (35) with the polishing roller (37) and the supporting shell (34), and the pin shaft (342) is separated from the extending part (321); when the blade (41) rotates forward and enters the polishing gap, the blade (41) rotates in the opposite direction with the polishing roller (37) and the support shell (34), and the pin shaft (342) is pressed into the inner side of the extension portion (321) through the hemispherical top end thereof.

4. A clamping and polishing device for pump body machining according to claim 3, characterized in that the impeller seat (2) is internally provided with a placement cavity positioned below the impeller groove, a motor (5) is arranged in the placement cavity, and an output shaft of the motor (5) is coaxially connected with the impeller (4).

5. The clamping and polishing device for pump body machining according to claim 4, wherein a pressure sensor (3411) is arranged on the guide rail (31), a controller is arranged in the machine case (1), the pressure sensor (3411) is connected with the motor (5) through the controller, when the polishing roller (37) is out of contact with the blade (41) in a reverse rotation state, the pin shaft (342) is in contact with the pressure sensor (3411), and the pressure sensor (3411) changes the steering direction of the motor (5) according to pressure change.

6. The clamping and polishing device for pump body machining according to claim 5, wherein the clamping piece comprises a clamping ring plate (14), the clamping ring plate (14) is clamped at a hub of the impeller (4), a position sensor (313) is arranged at one end, close to the telescopic device (13), of the guide rail (31), the position sensor (313) is connected with the motor (5) through the controller, when the polishing roller (37) polishes the blade (41) from outside to inside, the supporting shaft (35) is driven to slide along the length direction of the T-shaped sliding groove (311), and when the supporting shaft (35) reaches a preset position of the position sensor (313), the position sensor (313) changes the steering direction of the motor (5) through the controller.

7. Clamping and polishing device for pump body machining according to claim 2, characterized in that the guide rail (31) is detachably connected to the output end of the telescopic device (13), the number of blades (41) is even, and the polishing assembly (3) has two and is symmetrical with respect to the axis of the impeller (4).

8. Clamping and polishing device for pump body processing according to claim 2, characterized in that a collecting assembly is arranged in the chassis (1), and the collecting assembly comprises:

the dirt collecting box (6) is positioned below the impeller seat (2) and is arranged on the case (1);

exhaust fan (7), the first end of exhaust fan (7) is towards impeller (4) department on impeller seat (2), exhaust fan (8) are installed to the lateral wall of dirt collection box (6), the second end of exhaust fan (7) with exhaust fan (8) intercommunication.

9. Clamping and polishing device for pump body machining according to claim 8, characterized in that the first end of the suction pipe (7) is horn-shaped towards the impeller (4).

10. Clamping and polishing device for pump body processing according to claim 8, characterized in that the suction fans (7) are two and symmetrical with respect to the axis of the impeller (4) on the impeller seat (2), the number of suction fans (8) and the number of suction fans (7) are equal and correspond one to one, and the suction fans (8) are communicated with the corresponding suction fans (7).